FR3040567B1 - TUBULAR ELECTRIC MOTOR COMPRISING A BRAKING SYSTEM WITH MAGNETIC BRAKING MEANS - Google Patents

Abstract

The present invention relates to a braking system for braking an electric motor (2), said electric motor (2) comprising a rotor (21) rotatable and comprising a magnet, a stator (22) carrying a plurality of coils (14). said braking system comprising: switching means (11) coupled to said plurality of coils (14) and control means (7) adapted to control said switching means (11) to short-circuit each of said plurality of coils (14).

Description

BRAKING SYSTEM AND METHOD OF BRAKING AN ELECTRIC MOTOR

TECHNICAL AREA

According to a first aspect, the invention relates to a braking system for braking an electric motor. According to a second aspect, the invention relates to a braking method for braking an electric motor.

PRIOR ART

Electric motors are well known. They allow for example to use electrical energy to rotate a motor shaft which itself can lead for example the driving wheels of a car, a closure element (a flap for example). In general, an electric motor comprises a stationary stator having a central recess and a rotor that is rotatable within the central recess of the stator. There are different ways to rotate the rotor inside the stator. One method is to use a rotor comprising a magnet and to impose a rotating magnetic field within the central recess of the stator. The rotor magnet then experiences a force that tends to align with the rotating magnetic field of the stator. In the end, the rotor turns. To impose the rotating magnetic field of the stator, one method is to use coils (or electromagnets) arranged along the stator. By imposing a specific electric current in each of the coils, it is possible to obtain a rotating magnetic field in the central recess of the stator. In general, the output torque of the electric motor and the rotational speed of the rotor can be controlled with the intensity and frequency of currents flowing through the coils. In particular, by cutting the power supply of the coils, the rotor stops. Nevertheless, after stopping the supply of the stator coils, the rotor continues to rotate for a certain time because of its inertia. Braking systems have been developed to be able to brake the stator because it is often desired or necessary to have a control on the end of rotation of the rotor. In most situations, it is not possible to wait for the rotor to stop on its own once the power supply to the coils is cut off.

Known braking systems have certain disadvantages. For many of them, it is necessary to provide specific additional elements such as for example permanent magnets specially dedicated to a brake function. This increases the costs and makes the manufacture of an electric motor with such a braking system longer and more complicated. This also increases the size of such electric motors. On the other hand, the known braking systems are generally not effective enough to allow a rapid stop rotor.

SUMMARY OF THE INVENTION

According to a first aspect, the inventors propose a braking system for braking an electric motor which is simple to implement and which makes it possible to have additional braking power compared with known braking systems. To this end, the inventors propose the following braking system: braking system for braking an electric motor, said electric motor comprising: a rotatable rotor comprising a magnet, a stator carrying a plurality of coils and having a central recess for allow rotation of said rotor within said stator. The braking system of the invention is characterized in that it comprises: switching means coupled to said plurality of coils and control means adapted to control said switching means to short-circuit each of the coils of said plurality of coils.

The braking system of the invention is simple to implement. It only requires switching means and control means. These control means may be the same as those which generally control the current flowing in the stator coils. The number of elements specifically dedicated to the braking system of the invention is therefore greatly reduced. This simplifies the implementation of the braking system and limits the associated costs.

The braking system of the invention makes it possible to have an additional braking power with respect to known braking systems. When it is decided to brake the electric motor, the control means send a signal to the switching means to put each of the stator coils shorted. This term is known to a person skilled in the art. A coil generally comprises two terminals: a current input terminal and a current output terminal when the coil is energized. Short-circuiting a coil means electrically connecting both terminals with as little electrical resistance as possible. Once the braking system of the invention is activated, each coil is short-circuited. When one decides to stop the electric motor, the rotor turns in general. Each coil therefore undergoes a variation in magnetic flux induced by the rotation of the rotor. Each coil opposes this variation by creating a magnetic counterflow. In each coil, the electromotive force induced by the variation of magnetic flux creates a current in the coil and therefore a magnetic flux. This magnetic counterflow can be important with the braking system of the invention since the coils are short-circuited on themselves (the induced electromotive force creates a current which can be important in each short-circuited coil, and therefore a flux magnetic). The counterflows created by the short-circuited coils slow down the rotation of the rotor which comprises a magnet.

The braking system of the invention can be used in addition to one or more other braking systems for braking an electric motor.

Preferably, the electric motor is a brushless electric motor often called brushless.

Preferably, the rotor magnet is a permanent magnet. Preferably, the control means are programmed to control the switching means for shorting each coil.

Preferably, the control means comprise a controller. Preferably, this controller is a microcontroller.

Preferably, the switching means comprise a switch. According to a still preferred version, the switching means comprise a set of several switches. Other switching means known to those skilled in the art can be used.

Preferably, said plurality of coils comprises coils able to be supplied with out-of-phase currents. According to this preferred variant, there are therefore different coils fed by different phases or by currents out of phase. Preferably, there are three different phases shifted each by 120 °. There are then preferably three coils or an integer multiple of three coils. In this preferred embodiment, the different coils supplied by the different phases are short-circuited when it is desired to brake the electric motor.

The inventors also propose an assembly comprising an electric motor and a braking system as described above.

Preferably, the electric motor is a tubular motor. Preferably, the electric motor is a permanent magnet electric motor. Preferably, the electric motor is a brushless motor.

According to a second aspect, the inventors propose a braking method for braking an electric motor which comprises: a rotatable rotor comprising a magnet; a stator carrying a plurality of coils and having a central recess for allowing said rotor to rotate inside said stator.

The braking braking method according to the invention comprises a step of short-circuiting each of said plurality of coils.

The advantages presented for the braking system apply to the braking method, mutatis mutandis. In particular, the braking method according to the invention is particularly simple to implement, inexpensive and allows to have additional braking power.

Preferably, the step of shorting each of said plurality of coils comprises a step of sending a control signal to switching means coupled to the coils of said plurality of coils so that they are short-circuited. -circuit each coil of said plurality of coils.

Preferably, said control signal is sent to said switching means when a braking command signal is received by control means (a controller or a microcontroller for example).

SUMMARY DESCRIPTION OF THE FIGURES Other advantages and features will become more apparent from the following description of several variant embodiments, given by way of non-limiting example, with reference to the appended drawings, in which: FIG. a door with a closure element; FIG. 2 shows an example of an electric motor; FIG. 3 shows a sectional view of an example of an electric motor according to the invention; FIG. 4 shows an example of switching means and control means of the braking system of the invention in combination with other elements which make it possible to control the current flowing in coils of a stator.

The different figures are not necessarily scaled.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

According to a first aspect, the invention relates to a braking system for braking an electric motor 2. This electric motor 2 can be used to drive various elements such as for example: the wheels of a car, a blade of a household appliance , a closure element 1. Examples of closure elements 1 are: a blind, a shutter, a curtain. The invention is detailed when the electric motor 2 is used to drive a closure element 1. One skilled in the art will understand without difficulty that the invention can be used when the electric motor 2 is used for other applications.

Figure 1 shows a house 30 which includes an opening 20. In the example of Figure 1, the opening 20 is a door. Another example of opening 20 is a window. A closure element 1 makes it possible to conceal or close the opening 20. Examples of closure element 1 are: a shutter, a blind, a shutter, a fabric. This closure element 1 may describe a deployment movement (or closing movement, occultation) for closing the opening 20. In the example shown in Figure 1, this corresponds to a downward movement, L Closure member 1 may also describe a retracting movement (or opening, disengaging movement) for disengaging or releasing aperture 20. In the example shown in FIG. 1, this corresponds to an upward movement.

In general, the closure element 1 is mechanically coupled to an electric motor 2 which can impose these movements of deployment and retraction. Different types of electric motors can be used. Preferably, the output of the motor 2 is coupled to a gearbox (for example an epicyclic reduction gear) which is itself mechanically coupled to the closure element 1. Preferably, there is furthermore a mechanical brake which makes it possible to avoid the deployment of the closure element 1 in the absence of power supply of the motor 2.

An example of an electric motor 2 that can be used is a tubular asynchronous motor. Another more recent example of an electric motor 2 that can be used is a tubular motor with brushless permanent magnets operating without brushes. Such an electric motor 2 comprises a wound stator 22 while magnets are placed on the rotor 21, an electronic control system ensuring the switching of current in the stator windings.

According to a preferred variant, the electric motor 2 is a tubular electric motor with permanent magnets comprising at least one rotor 21 consisting of at least one permanent magnet extending through a stator 22 carrying a plurality of coils 14, said stator 22 being consisting of a plurality of assembled rings, each ring having a central recess 16 for the passage of the rotor 21 and a plurality of inverted T-shaped radial teeth extending towards the center of said ring, said radial teeth respectively receiving the coils 14, the ratio between the surface of the teeth and the surface of the spaces between said teeth being between 0.3 and 0.7. Compared to other electric motors 2 known, this preferred variant has the following advantages: less bulky, sufficient torque to unwind / wind a shutter or blind, less noise.

FIG. 2 schematically shows this preferred variant of the electric motor 2 in combination with a gearbox 3. This electric motor 2 also comprises two flanges 23 on either side of the stator 22.

FIG. 3 shows a sectional view of an example of an electric motor 2 according to the invention. In this example, the stator 22 comprises three coils 14. Preferably, these three coils 14 may be supplied by currents out of phase by 120 ° relative to each other.

The braking system of the invention comprises switching means 11 coupled to the coils 14 of the stator 22 and control means 7 designed for (for example, programmed to) control said switching means 11 to short-circuit each of said plurality of coils 14. Preferably, the switching means 11 are electrically coupled to the coils 14 of the stator 22.

FIG. 4 shows an example of switching means 11 and control means 7 of the braking system of the invention in combination with other elements which make it possible to control the current flowing in the coils 14 of the stator 22.

Different types of switching means 11 may be used. The switching means 11 may for example comprise one or more switches. The control means 7 may for example be a microcontroller specifically programmed to control the switching means 11 so that the latter can short-circuit the coils 14 of the stator 22 when a specific signal is received by the microcontroller.

In the example shown in Figure 4, the electric motor 2 can be powered by three different phases (u, v, w). For example, the electric motor 2 comprises three coils 14 (example of FIG. 3) and each can be powered by a current shifted by 120 ° with respect to the current supplying another coil 14. In this case, the switching means 11 are capable of shorting each coil 14 of each phase.

In addition to the switching means 11 and the control means 7 of the braking system, FIG. 4 shows elements that can be used to control the current flowing in the coils 14. These elements comprise: at least one electromagnetic compatibility filter said CEM 17, - a power factor correction circuit 18, - a rectifying and filtering circuit 19, - a circuit comprising insulated gate bipolar transistors known as IGBT 6 (term known to those skilled in the art) in order to supplying the supply voltage (s) to the coils 14, - a microcontroller 7 capable of determining and transmitting the control signals to the IGBT transistor circuit 6, - one or more shunts 4 (or low resistors) for measuring currents flowing in the coils 14. These current measurements are useful for controlling the electric motor 2 by means of the microcontroller 7; one or more other circuits which can for example be used to know the angular position of the rotor 21.

The EMC filter 17 is preferably a filter making it possible to reduce or even prevent currents induced on cables that can disturb the operation of the various elements. This EMC filter 17 may for example perform frequency filtering and / or temporal filtering and / or voltage clipping. Other filters known to those skilled in the art can be used to suppress electromagnetic disturbances in ducts and radiated mode. The power factor corrector circuit 18 makes it possible, in the usual manner, to eliminate the deformations of the electrical network on the current absorbed to avoid the appearance of harmonic currents polluting the network on the one hand, and to put the current and the voltage in phase on the other hand. The rectifying and filtering circuit 19 ensures the DC bus voltage.

Preferably, the rotor 21 consists of a magnetized plastoferrite cylinder, fitted and glued on a shaft. By plastoferrite is meant a material composed of ferrite powder mixed with a thermoplastic binder. Such a plastoferrite cylinder can be obtained by any method of molding and / or machining a plastoferrite material known to those skilled in the art. Preferably, the outer wall of the plastoferrite cylinder comprises at least one recess and / or at least one longitudinal recess. The plastoferrite cylinder could be replaced by a Neoplat or Feplast cylinder. Other examples are also possible.

Preferably, the rotor 21 extends between two bearings not shown in FIGS. 2 and 3.

In addition to the braking system of the invention, it is possible to provide another braking system (for example a magnetic braking system) for the electric motor 2. For example, it is possible to affix additional permanent magnets on a part of the rotor 21 which are used as magnetic brake. These additional permanent magnets are magnetically coupled to other permanent magnets present on a part of the stator 22. This magnetic coupling makes it possible to provide additional braking and / or to help keep the rotor 21 stopped when the coils 14 are not electrically powered. When the electrical energy supplied to the coils 14 is sufficient, the driving torque of the electric motor 2 is greater than the braking torque provided by the magnetic braking system, which allows the rotor 21 to be rotated. On the contrary, when the electrical energy supplied to the coils 14 is insufficient, the engine torque is less than the magnetic braking torque, allowing the slowdown of the rotor 21 when the latter rotates. In addition, by using the braking system according to the invention, the braking is all the more effective.

In summary, the invention can also be described as follows. A braking system for braking an electric motor 2, said electric motor 2 comprising a rotor 21 adapted to rotate and comprising a magnet, a stator 22 carrying a plurality of coils 14, said braking system comprising: switching means 11 coupled to said plurality of coils 14 and control means 7 for controlling said switching means 11 to short-circuit each of said plurality of coils 14.

Claims (7)

A tubular electric motor comprising: a rotor (21) rotatable and comprising at least one magnet; a stator (22) carrying a plurality of coils (14) and having a central recess (16) to allow rotation of said rotor (21) within said stator (22); a braking system of said electric motor; characterized in that said braking system comprises: magnetic braking means consisting of additional permanent magnets secured to a portion of the rotor (21) and magnetically coupled to permanent magnets integral with a portion of the stator (22); switching means (11) coupled to said plurality of coils (14) and control means (7) adapted to control said switching means (11) to short-circuit each of said coils (14) of said plurality of coils (14). coils (14). 2. Tubular electric motor according to the preceding claim characterized in that said control means (7) comprise a microcontroller. 3. Tubular electric motor according to any one of the preceding claims characterized in that said switching means (11) comprise a switch. 4. Tubular electric motor according to any one of the preceding claims characterized in that said electric motor (2) is adapted to feed coils (14) of said plurality of coils (14) with currents out of phase. 5. Tubular electric motor according to any one of claims 1 to 4 characterized in that the stator (22) comprises three coils (14) respectively powered by a phase-shifted current of 120 ° relative to the current supplying another coil (14). . 6. Tubular electric motor according to any one of claims 1 to 5 characterized in that the rotor (21) consists of a magnetized plastoferrite cylinder, fitted and glued on a shaft. 7. Tubular electric motor according to any one of claims 1 to 6 characterized in that the stator (22) consists of a plurality of assembled rings, each ring having a central recess (16) for the passage of the rotor (21). ) and a plurality of inverted T-shaped radial teeth extending towards the center of said ring, said radial teeth respectively receiving the coils (14).